Apparatus and method for measuring current and voltage of secondary battery pack in synchronization manner

ABSTRACT

Provided is an apparatus for measuring current and voltage of a secondary battery pack in synchronization manner, comprising a voltage measurement circuit for periodically measuring and outputting the level of a charging voltage of each of a plurality of battery cells contained in a battery pack; a current measurement circuit for periodically measuring and outputting the level of current flowing into or out of the battery pack; and a control unit for synchronizing a time difference between a current measurement time point of the battery pack and a voltage measurement time point of each battery cell with a reference delay time.

CROSS-REFERENCE TO RELATED APPLICATION

This application is a continuation of International Application No. PCT/KR2009/006559 filed on Nov. 9, 2009, which claims priority to Korean Patent Application No. 10-2008-0111068 filed in Republic of Korea on Nov. 10, 2008, and Korean Patent Application No. 10-2009-0107638 filed in Republic of Korea on Nov. 9, 2009, the entire contents of which are incorporated herein by reference.

TECHNICAL FIELD

The present invention relates to an apparatus and method for measuring current and voltage of a secondary battery, and more specifically, to an apparatus and method for measuring current and voltage of a secondary battery pack in synchronization manner that is capable of accurately measuring current and voltage of the battery pack by synchronizing a current measurement time point and a voltage measurement time point to estimate an internal resistance of the battery pack having a plurality of battery cells connected in series.

BACKGROUND ART

Recently, interests in electric vehicles or hybrid vehicles running on electrical energy, not on fossil energy, are increasing due to concern about exhaustion of fossil energy and environmental pollution.

The electric vehicles or hybrid vehicles mainly use secondary batteries capable of charging and discharging repeatedly. Here, discharging is the conversion of chemical energy into electrical energy and charging is the conversion of electrical energy into chemical energy. The secondary batteries include nickel cadmium batteries, nickel hydrogen batteries, lithium ion batteries, lithium ion polymer batteries and so on.

In particular, a high capacity battery pack, in which a plurality battery cells are connected in series, is used in operating a high-power electric motor required to run the electric vehicles or hybrid vehicles.

It is important for the electric vehicles or hybrid vehicles to display the residual electrical energy of a battery so that a user can estimate the distance to empty. Conventional gasoline vehicles operate the engine using fuel, and thus, do not have great difficulty in measuring the amount of fuel. However, while the electric vehicles or hybrid vehicles are being charged or discharged, there is a difference between the measured properties (voltage, internal resistance and so on) and actual properties due to nonlinearity of electrochemical properties, aging effects, IR drop phenomenon and so on. Thus, the electric vehicles or hybrid vehicles have difficulty in accurately measuring electrical energy remaining in a battery during traveling. Currently, the residual electrical energy of a battery is measured by estimating the state of charge (SOC) of the battery. Meanwhile, the state of health (SOH) is also used as an indicator of the state of a battery. Because the characteristics of batteries change over time, SOH serves as an index of aging effects. The quantitative estimation of SOH allows for a user to know in advance how much electrical energy of a battery is available. A typical parameter used for SOH estimation is an internal resistance of a battery. The internal resistance is difficult to accurately measure during the use of a battery. Thus, the internal resistance is measured in the state that the use of a battery is stopped, or indirectly estimated during the use of a battery.

The internal resistance of a battery may be estimated by calculating a rate of voltage of each battery cell in the battery to a charging or discharging current of the battery. For more accurate estimation of the internal resistance, it needs to synchronize a current measurement time point with a voltage measurement time point. Here, synchronization of current and voltage measurement time points does not literally mean an exact synchronization of a current measurement time point with a voltage measurement time point, but making a time difference between a voltage measurement time point and a current measurement time point. As batteries operate by electrochemical reaction, when changes in electric current occur, it takes a predetermined time till voltages at opposite ends of the battery change, due to the internal resistance. Conventionally, since it is difficult to accurately measure current and voltage of a battery after synchronization of current and voltage measurement time points, the internal resistance is calculated by continuously measuring current of the battery at a shorter current measuring cycle than a voltage measuring cycle, measuring voltage of the battery when estimation of the internal resistance is necessary, and selecting a value of current measured immediately before the voltage measurement time point.

However, the conventional technique has a drawback that frequent sampling of electric current measurement results in overload applied on a host processor of a battery management system which controls the overall current and voltage measurement. The overload causes malfunction or operating speed reduction of the host processor of the battery management system. And, if current and voltage are measured in the state that a current measurement time point is not exactly synchronized with a voltage measurement time point, an internal resistance estimated from the measured current and voltage is not correct, either.

Meanwhile, even though a current measurement time point is synchronized with a voltage measurement time point, the synchronized state is not continuously maintained. This is because if the host processor of the battery management system suffers from performance changes due to overheat, overload and so on, a small error occurs to the synchronized state of current and voltage measuring cycles, and the error accumulates and becomes larger as time passes.

DISCLOSURE OF INVENTION

Technical Problem

It is an object of the present invention to solve the problems of the conventional art, and therefore, the present invention provides an apparatus and method for measuring current and voltage of a secondary battery pack in synchronization manner that is capable of accurately measuring current and voltage of the battery pack by synchronizing a current measurement time point and a voltage measurement time point to estimate an internal resistance of the battery pack having a plurality of battery cells connected in series.

Technical Solution

The present invention may provide an apparatus for measuring current and voltage of a secondary battery pack in synchronization manner, comprising a voltage measurement circuit for periodically measuring and outputting the level of a charging voltage of each of a plurality of battery cells contained in a battery pack; a current measurement circuit for periodically measuring and outputting the level of current flowing into or out of the battery pack; and a control unit for synchronizing a time difference between a current measurement time point of the battery pack and a voltage measurement time point of each battery cell with a reference delay time.

Preferably, the reference delay time is a time preset using trial and error.

According to an aspect of the present invention, a sampling period of the voltage measurement is equally fixed.

When a sampling period of the voltage measurement is equally fixed, if there is a time error between a reference delay time and a time difference between a current measurement time point of the battery pack and a voltage measurement time point of a K^(th) battery cell, the control unit adjusts a next current measurement time point of the battery pack by the time error based on a voltage measurement time point of a K+1^(th) battery cell.

And, the voltage measurement time point of the battery cell may be earlier or later than the current measurement time point of the battery pack.

And, the control unit adjusts a first current measurement time point of a next measuring cycle using a time error information obtained at the last current and voltage measurement time points of a previous measuring cycle.

According to another aspect of the present invention, a sampling period of the current measurement is equally fixed.

When a sampling period of the current measurement is equally fixed, if there is a time error between a reference delay time and a time difference between a current measurement time point of the battery pack and a voltage measurement time point of a K^(th) battery cell, the control unit adjusts a voltage measurement time point of a K+1^(th) battery cell by the time error based on a next current measurement time point of the battery pack.

And, the current measurement time point of the battery pack may be earlier or later than the voltage measurement time point of the battery cell.

And, the control unit adjusts a first voltage measurement time point of a next measuring cycle using a time error information obtained at the last current and voltage measurement time point of a previous measuring cycle.

Preferably, a sampling period of the voltage or a current measurement is longer than a time difference between current measurement time point and a voltage measurement time point adjacent to each other.

The present invention may also provide a battery management system, a battery pack operating apparatus and a secondary battery pack, comprising the apparatus for measuring current and voltage of a secondary battery pack in synchronization manner according to the present invention.

The present invention may also provide a method for measuring current and voltage of a secondary battery pack in synchronization manner, comprising the steps of (a) periodically measuring current of a battery pack and voltage of each of a plurality of battery cells contained in the battery pack; and (b) synchronizing a time difference between a current measurement time point of the battery pack and a voltage measurement time point of each battery cell with a reference delay time.

And, the present invention may provide a computer readable storage medium containing, as a program, the method for measuring current and voltage of a secondary battery pack in synchronization manner according to the present invention.

Furthermore, the present invention may provide a hardware module, such as a microprocessor, for performing each step required to measure current and voltage of a secondary battery pack in synchronization manner according to the present invention.

The hardware module according to the present invention may perform the processes of periodically measuring current of a batter pack having a plurality of battery cells connected in series and voltage of each battery cell, comparing a reference delay time with a time difference between a current measurement time point of the battery pack and a voltage measurement time point of each battery cell, and calculating a time error between the reference delay time and the time difference, and synchronizing the current measurement time point with the voltage measurement time point by reflecting the calculated error on a next current measurement time point of the battery pack or a voltage measurement time point of a next battery cell.

BRIEF DESCRIPTION OF THE DRAWINGS

The accompanying drawings illustrate the preferred embodiments of the present invention and are included to provide a further understanding of the sprit and scope of the present invention together with the detailed description of the invention, and accordingly, the present invention should not be limitedly interpreted to the matters shown in the drawings.

FIG. 1 is a schematic circuit diagram of an apparatus for measuring current and voltage of a secondary battery pack in synchronization manner according to a preferred embodiment of the present invention.

FIG. 2 is a timing diagram illustrating adjustment of a current measurement time point and a voltage measurement time point according to an embodiment of the present invention.

FIG. 3 is a timing diagram illustrating adjustment of a current measurement time point and a voltage measurement time point according to another embodiment of the present invention.

FIG. 4 is a flowchart of a method for measuring current and voltage of a secondary battery pack in synchronization manner according to an embodiment of the present invention.

FIG. 5 is a flowchart of a method for measuring current and voltage of a secondary battery pack in synchronization manner according to another embodiment of the present invention.

BEST MODE

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to the description, it should be understood that the terms used in the specification and the appended claims should not be construed as limited to general and dictionary meanings, but interpreted based on the meanings and concepts corresponding to technical aspects of the present invention on the basis of the principle that the inventor is allowed to define terms appropriately for the best explanation. Therefore, the description proposed herein is just a preferable example for the purpose of illustrations only, not intended to limit the scope of the invention, so it should be understood that other equivalents and modifications could be made thereto without departing from the spirit and scope of the invention.

FIG. 1 is a schematic circuit diagram of an apparatus for measuring current and voltage of a secondary battery pack in synchronization manner according to a preferred embodiment of the present invention.

Referring to FIG. 1, the apparatus for measuring current and voltage of a secondary battery pack in synchronization manner according to the present invention, comprises a current measurement circuit 20, a voltage measurement circuit 30, and a control unit 40. The apparatus synchronizes a current measurement time point with a voltage measurement time point for each battery cell V₁, V₂, V₃ and V₄ of a battery pack 10 having a plurality of battery cells V₁, V₂, V₃ and V₄ connected in series, and measures current and voltage of the secondary battery pack in synchronization manner. Although FIG. 1 shows four battery cells, the present invention is not limited to a specific number of battery cells.

The battery pack 10 is an electrical energy storage means, and contains a plurality of rechargeable battery cells V₁, V₂, V₃ and V₄ connected in series. The battery cells V₁, V₂, V₃ and V₄ are secondary batteries, for example, nickel cadmium batteries, nickel hydrogen batteries, lithium ion batteries, lithium ion polymer batteries and so on. However, the present invention is not limited to a specific type of secondary battery.

The current measurement circuit 20 is electrically connected with opposite ends of the battery pack 10 having a plurality of battery cells V₁, V₂, V₃ and V₄ connected in series. The current measurement circuit 20 measures the level of a discharging current flowing out of the battery pack 10 or the level of a charging current flowing into the battery pack 10. Here, because the battery cells V₁, V₂, V₃ and V₄ contained in the battery pack 10 are connected in series, the level of current of the battery cells V₁, V₂, V₃ and V₄ may be represented as the level of current flowing into or out of the battery pack 10.

The voltage measurement circuit 30 is electrically connected with each battery cell V₁, V₂, V₃ and V₄, respectively, contained in the battery pack 10. The voltage measurement circuit 30 sequentially measures the level of a charging voltage of each battery cell V₁, V₂, V₃ and V₄ on a regular cycle.

The control unit 40 periodically controls the current measurement circuit 20 and the voltage measurement circuit 30 to adjust a current measurement time point of the battery pack 10 and a voltage measurement time point of each battery cell V₁, V₂, V₃ and V₄, thereby measuring current and voltage of each battery cell in synchronization manner.

The control unit 40 has a memory (not shown), and can store a current measurement value and a voltage measurement value outputted from the current measurement circuit 20 and the voltage measurement circuit 30 in the memory. The control unit 40 may also have a program algorithm in the memory for enabling current and voltage measurement of each battery cell in synchronization manner.

When the control unit 40 initiates its operation, the control unit 40 loads said program algorithm that enables current and voltage measurement of each battery cell in synchronization manner.

Next, the control unit 40 controls the current measurement circuit 20 to measure current of the battery pack 10 and store a current measurement time point in the memory. And, the control unit 40 controls the voltage measurement circuit 30 to measure voltage of a first battery cell V_(I) on at a measuring time point according to a preset sampling period of voltage measurement and stores a voltage measurement time point in the memory. Here, the sampling period of voltage measurement is equally fixed, and may be longer than a time difference between a current measurement time point and a voltage measurement time point adjacent to each other.

Next, the control unit 40 calculates a time difference between the current measurement time point of the battery pack 10 stored in the memory and the voltage measurement time point of the battery cell V₁ stored in the memory. Then, the control unit 40 compares the calculated time difference with a reference delay time and calculates a time error therebetween. Here, the reference delay time is a data preset using trial and error that was executed in advance. That is, an internal resistance of a battery cell of which an internal resistance is exactly known is actually calculated while varying a current measurement time point and a voltage measurement time point of the battery cell, and when a discrepancy between the calculated internal resistance and the already known internal resistance is minimum, a time difference between a current measurement time point and a voltage measurement time point is set as a reference delay time.

Next, the control unit 40 adjusts the preset sampling period of current measurement by the time error calculated by comparing the time difference between current and voltage measurement time points with the reference delay time, measures current of the battery pack 10 on a next measuring time point according to the adjusted sampling period, and stores a current measurement time point in the memory. And, the control unit 40 measures voltage of a next battery cell V₂ according a preset sampling period of voltage measurement, and stores a voltage measurement time point in the memory. And, the control unit 40 repeatedly applies this process to the other battery cells V₃ and V₄, said process comprising synchronizing a next current measurement time point of a battery pack with a voltage measurement time point of a next battery cell using a time error calculated by comparing a reference delay time with a time difference between the current measurement time point and the voltage measurement time point.

Although this embodiment shows that a voltage measurement time point of each battery cell V₁, V₂, V₃ and V₄ is later than a current measurement time point of the battery pack 10, a voltage measurement time point of each battery cell V₁, V₂, V₃ and V₄ may be earlier than a current measurement time point of the battery pack 10. And, it is possible to synchronize a current measurement time point with a voltage measurement time point while equally fixing a sampling period of current measurement of the battery pack 10 and varying a sampling period of voltage measurement of each battery cell V₁, V₂, V₃ and V₄. At this time, it is obvious that a voltage measurement time point of each battery cell V₁, V₂, V₃ and V₄ may be earlier or later than a current measurement time point of the battery pack 10.

FIG. 2 is a timing diagram illustrating adjustment of a current measurement time point and a voltage measurement time point according to an embodiment of the present invention.

FIG. 2 illustrates voltage measurement time points V_(n), V_(n+1), V_(n+2), V_(n+3), V_(n+4), V_(n+5), . . . of a plurality of battery cells and current measurement time points of a battery pack over time. In FIG. 2, a sampling period of voltage measurement time point V_(n), V_(n+1), V_(n+2), V_(n+3), V_(n+4), V_(n+5), . . . is equal for each battery cell. And, a voltage measurement time point V_(n), V_(n+1), V_(n+2), V_(n+3), V_(n+4), V_(n+5), . . . is later than a current measurement time point in each battery cell. Case 1 to Case 3 show cases that may be resulted from comparison of a time difference T_(n), T_(n+1), T_(n+2), T_(n+3), T_(n+4), T_(n+5), . . . between a current measurement time point and a voltage measurement time point with a reference delay time ΔT.

Hereinafter, described in detail is a method for synchronizing a current measurement time point with a voltage measurement time point by adjusting the current measurement time point based on the voltage measurement time point for each battery cell per each case.

<Case 1>

Case 1 is a case that a reference delay time ΔT is smaller than a time difference T_(n) between a current measurement time point I_(n) for estimating an internal resistance of an n^(th) battery cell and a voltage measurement time point V_(n) of the n^(th) battery cell. In this case, if an n+1^(th) current is measured according to a preset sampling period T, of current measurement without correcting an n+1^(th) current measurement time point I_(n+1) based on a voltage measurement time point V_(n+1) of an n+1^(th) battery cell, a time error with the reference delay time ΔT occurs when the n+1^(th) current measurement is performed. As a result, a current measurement time point of the n+1^(th) battery cell is not synchronized with a voltage measurement time point of the n+1^(th) battery cell. However, the present invention removes the time error occurred in the n^(th) measuring cycle by reflecting the time error on an n+1^(th) sampling period T_(s() _(n+1)) of current measurement. That is, a current measurement time point I_(n+1) for estimating an internal resistance of an n+1^(th) battery cell is delayed by said time error. Then, a time difference T_(n+1) between the n+1^(th) current measurement time point I_(n+1) and the voltage measurement time point V_(n+1) of the n+1^(th) battery cell becomes equal to the reference delay time ΔT, so that a current measurement time point can be synchronized with a voltage measurement time point.

<Case 2>

Case 2 is a case that a reference delay time ΔT is larger than a time difference T_(n+2) between a current measurement time point I_(n+2) for estimating an internal resistance of an n+2^(th) battery cell and a voltage measurement time point V_(n+2) of the n+2^(th) battery cell. In this case, similarly to the case 1, a current measurement time point is not synchronized with a voltage measurement time point, and a time error occurs. However, the present invention reflects the time error occurred in the n+2^(th) measuring cycle on an n+3^(th) sampling period T_(s(n+3)) of current measurement. That is, a current measurement time point I_(n+3) for estimating an internal resistance of an n+3^(th) battery cell is advanced by said time error. Then, a time difference T_(n+3) between the n+3 ^(th) current measurement time point I_(n+3) and the voltage measurement time point V_(n+3) of the n+3^(th) battery cell becomes equal to the reference delay time ΔT, so that a current measurement time point can be synchronized with a voltage measurement time point.

<Case 3>

Case 3 is a case that a reference delay time ΔT is equal to a time difference T_(n+4) between a current measurement time point I_(n+4) for estimating an internal resistance of an n+4^(th) battery cell and a voltage measurement time point V_(n+4) of the n+4^(th) battery cell. In this case, even though an n+5^(th) current is measured according to a preset sampling period T_(s) of current measurement without correcting an n+5^(th) current measurement time point I_(n+5) based on a voltage measurement time point V_(n+5) of an n+5^(th) battery cell, a time error with the reference delay time ΔT does not occur when the n+5^(th) current measurement is performed. Accordingly, the preset sampling period T, of current measurement is applied to this case 3 as it is. That is, any change does not occur at the current measurement time point I_(n+5) for estimating an internal resistance of the n+5^(th) battery cell. Then, a time difference T_(n+5) between the n+5 ^(th) current measurement time point I_(n+5) and the voltage measurement time point V_(n+5) of the n+5 ^(th) battery cell is equal to the reference delay time ΔT, so that a current measurement time point can be synchronized with a voltage measurement time point.

Although this embodiment shows that a voltage measurement time point V_(n), V_(n+1), V_(n+2), V_(n+3), V_(n+4), V_(n+5), . . . of each battery cell is later than a current measurement time point of a battery pack, a voltage measurement time point V_(n), V_(n+), V_(n+2), V_(n+3), V_(n+4), V_(n+5), . . . of each battery cell may be earlier than a current measurement time point of a battery pack. In this case, the same process as described above is equally applied, said process comprising synchronizing a current measurement time point with a voltage measurement time point in a next measuring cycle by calculating a time error between a voltage measurement time point and a current measurement time point in a present measuring cycle, and reflecting the calculated time error on a next sampling period of current measurement.

FIG. 3 is a timing diagram illustrating adjustment of a current measurement time point and a voltage measurement time point according to another embodiment of the present invention.

FIG. 3 illustrates voltage measurement time points V_(n), V_(n+1), V_(n+2), V_(n+3), V_(n+4), V_(n+5), . . . of a plurality of battery cells and current measurement time points of a battery pack over time. In FIG. 3, a sampling period of current measurement time point I_(n), I_(n+1), I_(n+2), I_(n+3), I_(n+4), I_(n+5), . . . of the battery pack is equal. And, a voltage measurement time point V_(n), V_(n+1), V_(n+2), V_(n+3), V_(n+4), V_(n+5), . . . is earlier than a current measurement time point in each battery cell. Case 1 to Case 3 show cases that may be resulted from comparison of a time difference T_(n), T_(n+1), T_(n+2), T_(n+3), T_(n+4), T_(n+5), between a current measurement time point and a voltage measurement time point with a reference delay time ΔT.

Hereinafter, described in detail is a method for synchronizing a current measurement time point with a voltage measurement time point by adjusting the voltage measurement time point based on the current measurement time point for each battery cell per each case.

<Case 1>

Case 1 is a case that a reference delay time AT is smaller than a time difference T_(n) between a voltage measurement time point V_(n), of an n^(th) battery cell for estimating an internal resistance of the n^(th) battery cell and an n^(th) current measurement time point I_(n). In this case, if voltage of an n+1^(th) battery cell is measured according to a preset sampling period T_(s) of voltage measurement without correcting a voltage measurement time point V_(n+1) of the n+1^(th) battery cell based on an n+1^(th) current measurement time point I_(n+1), a time error with the reference delay time ΔT occurs when measuring voltage of the n+1^(th) battery cell. As a result, a voltage measurement time point is not synchronized with a current measurement time point in an n+1^(th) measuring cycle. However, the present invention removes the time error by reflecting the time error occurred at the nth measuring cycle on an n+1^(th) sampling period T_(s(n+1)) of voltage measurement. That is, a voltage measurement time point V_(n+1) of an n+1^(th) battery cell for estimating an internal resistance of the n+1^(th) battery cell is delayed by said time error. Then, a time difference T_(n+1) between the voltage measurement time point V_(n+1) of the n+1^(th) battery cell and the n+1^(th) current measurement time point I_(n+1) becomes equal to the reference delay time ΔT, so that a voltage measurement time point can be synchronized with a current measurement time point.

<Case 2>

Case 2 is a case that a reference delay time ΔT is larger than a time difference T_(n+2) between a voltage measurement time point V_(n+2) of an n+2^(th) battery cell for estimating an internal resistance of the n+2^(th) battery cell and an n+2^(th) current measurement time point I_(n+2). In this case, similarly to the case 1, a voltage measurement time point is not synchronized with a current measurement time point, and a time error occurs. However, the present invention reflects the time error occurred in the n+2^(th) measuring cycle on an n+3^(th) sampling period T_(s(n+3)) of voltage measurement. That is, a voltage measurement time point V_(n+3) of an n+3^(th) battery cell for estimating an internal resistance of the n+3^(th) battery cell is advanced by said time error. Then, a time difference T_(n+3) between the voltage measurement time point V_(n+3) of the n+3^(th) battery cell and the n+3^(th) current measurement time point I_(n+3) becomes equal to the reference delay time ΔT, so that a voltage measurement time point can be synchronized with a current measurement time point.

<Case 3>

Case 3 is a case that a reference delay time ΔT is equal to a time difference T_(n+4) between a voltage measurement time point V_(n+4) of an n+4^(th) battery cell for estimating an internal resistance of the n+4^(th) battery cell and an n+4^(th) current measurement time point I_(n+4). In this case, even though voltage of an n+5^(th) battery cell is measured according to a preset sampling period T_(s) of voltage measurement without correcting a voltage measurement time point V_(n+5) of an n+5 ^(th) battery cell based on an n+5^(th) current measurement time point I_(n+5), a time error with the reference delay time ΔT does not occur when measuring voltage of the n+5^(th) battery cell. Accordingly, the preset sampling period T_(s) of voltage measurement is applied to this case 3 as it is. That is, any change does not occur at the voltage measurement time point V_(n+5) of the n+5^(th) battery cell for estimating an internal resistance of the n+5^(th) battery cell. Then, a time difference T_(n+5) between the voltage measurement time point V_(n+5) of the n+5^(th) battery cell and the n+5^(th) current measurement time point I_(n+5) is equal to the reference delay time ΔT, so that a voltage measurement time point can be synchronized with a current measurement time point.

Although this embodiment shows that a voltage measurement time point V_(n), V_(n+1), V_(n+2), V_(n+3), V_(n+4), V_(n+5), . . . of each battery cell is earlier than a current measurement time point of a battery pack, a voltage measurement time point V_(n), V_(n+1), V_(n+2), V_(n+3), V_(n+4), V_(n+5), . . . of each battery cell may be later than a current measurement time point of a battery pack. In this case, the same process as described above is equally applied, said process comprising synchronizing a voltage measurement time point with a current measurement time point in a next measuring cycle by calculating a time error between a voltage measurement time point and a current measurement time point in a present measuring cycle, and reflecting the calculated time error on a next sampling period of voltage measurement.

The control unit 40 performing the above-mentioned process may be implemented as a microprocessor capable of executing a source code into which a method for measuring current and voltage of a secondary battery pack in synchronization manner according to the present invention is programmed. Also, the control unit 40 may be implemented as an application-specific integrated circuit (ASIC) in which a control scheme of a method for measuring current and voltage of a secondary battery pack in synchronization manner according to the present invention is incorporated as a logic circuit. However, the present invention is not limited to a specific type of hardware for implementation of the control unit 40.

The apparatus for measuring current and voltage of a secondary battery pack in synchronization manner according to the present invention may be comprised in a battery pack operating apparatus that receives an electrical power from the battery pack.

For example, the apparatus according to the present invention may be comprised in various kinds of electronic devices that receive an operating power from a battery, such as notebook computers, mobile phones, portable multimedia players and so on.

Alternatively, the apparatus according to the present invention may be comprised in various driving apparatuses having batteries mounted therein, such as fossil fuel vehicles, electric vehicles, hybrid vehicles, electric bicycles and so on.

Furthermore, the apparatus according to the present invention may be implemented as a hardware module using a customized semiconductor technique such as a PCB circuit or ASIC. In this case, it is obvious to an ordinary person skilled in the art that the apparatus for measuring current and voltage of a secondary battery pack in synchronization manner may comprise a logic circuit module for implementing a function for measuring voltage of each battery cell and current of the battery pack in synchronization manner

The hardware module according to the present invention may perform a process for periodically measuring a current of a battery pack having a plurality of battery cells connected in series, periodically measuring voltage of each battery cell, comparing a reference delay time with a time difference between a current measurement time point of the battery pack and a voltage measurement time point of each battery cell, and calculating a time error. And, the hardware module may further perform a process for synchronizing a current measurement time point with a voltage measurement time point by reflecting the calculated time error on a next current measurement time point of the battery pack or a voltage measurement time point of a next battery cell. It is also obvious that the hardware module can equally perform various functions executed by the apparatus for measuring current and voltage of a secondary battery pack in synchronization manner, as well as the above-mentioned function.

FIG. 4 is a flowchart of a method for measuring current and voltage of a secondary battery pack in synchronization manner according to an embodiment of the present invention.

According to this embodiment of the present invention, a sampling period of voltage measurement for a plurality of battery cells included in a battery pack 10 are equally fixed, and a voltage measurement time point is later than a current measurement time point in each battery cell.

First, the control unit 40 executes a program algorithm that enables synchronization of current and voltage measurement time points to estimate an internal resistance of the battery pack 10 (S11).

The control unit 40 provides each battery cell and its current measurement order with an index K to sequentially measure current flowing into or out of the battery pack 10 and a charging voltage of each battery cell included in the battery pack 10, and initializes the index K to 1 (S21).

The control unit 40 controls the current measurement circuit 20 to measure a K^(th) current (K is 1 at present) of the battery pack 10, and stores a current measurement time point in the memory (S31).

The control unit 40 controls the voltage measurement circuit 30 to measure voltage of a K^(th) battery cell (K is 1 at present) according to a preset sampling period of voltage measurement, and stores a voltage measurement time point in the memory (S41).

The control unit 40 calculates a time difference between the current measurement time point and the voltage measurement time point stored in the memory through the steps S31 and S41 (S51).

The control unit 40 compares the calculated time difference between the current measurement time point and the voltage measurement time point calculated in the step S51 with a reference delay time stored in the memory, determines whether or not there is a time error, and calculates the time error, if any (S61).

The control unit 40 delays or advances a next current measurement time point of the battery pack 10 by the time error calculated in the step S61 (S71). That is, if the time error is larger than the reference delay time, the control unit 40 delays a next current measurement time point. On the contrary, if the time error is smaller than the reference delay time, the control unit 40 advances a next current measurement time point. And, if there is no time error, the control unit 40 does not delay or advance a next current measurement time point.

The control unit 40 determines if the index K is equal to the number of battery cells included in the battery pack 10 (S81). If the index K is equal to the number of battery cells, the process goes to the step S101. If the index K is smaller than the number of battery cells, the process goes to the step S91.

In the step S91, the control unit 40 increases the index K by 1 and the process goes to the step S31.

In the step S31, the control unit 40 enables a next current measurement of the battery pack 10 at a current measurement time point adjusted in the step S71, and stores a current measurement time point in the memory. Then, the control unit 40 performs subsequent steps equally as mentioned above, said subsequent steps comprising measuring voltage of a next battery cell, storing a voltage measurement time point in the memory, calculating a time difference between the current measurement time point and the voltage measurement time point, comparing the time difference with a reference delay time, determining whether or not there is a time error, calculating the time error, if any, and adjusting a next current measurement time point of the battery pack 10 by the calculated time error.

The control unit 40 repeatedly performs the steps S31 to S93 until the index K is equal to the number of battery cells. In this way, a current measurement time point of the battery pack 10 can be exactly synchronized with a voltage measurement time point of each battery cell.

In the step S101, the control unit 40 determines whether to continue to measure current of the battery pack 10 and voltage of each battery cell.

If it is determined that it does not need to continue to measure current of the battery pack 10 and voltage of each battery cell in the step S101 since operation of a load is stopped, the control unit 40 terminates the process for synchronizing a current measurement time point of the battery pack 10 with a voltage measurement time point of each battery cell.

On the contrary, if it is determined that it needs to continue to measure current of the battery pack 10 and voltage of each battery cell in the step S101 since the load continues to operate, the control unit 40 repeats the process for synchronizing a current measurement time point of the battery pack 10 with a voltage measurement time point of each battery cell. That is, the control unit 40 initializes the index K in the step S21. In the step S31, the control unit 40 enables a current measurement of the battery pack 10 and stores a current measurement time point in the memory. At this time, the current measurement time point is adjusted by a time error calculated from a time difference between a last current measurement time point of the battery pack and a voltage measurement time point of a last battery cell in a previous measuring cycle and a reference delay time. Then, the control unit 40 performs subsequent steps equally as mentioned above, said subsequent steps comprising measuring voltage of a battery cell, storing a voltage measurement time point in the memory, calculating a time difference between the current measurement time point and the voltage measurement time point, comparing the time difference with a reference delay time, determining whether or not there is a time error, calculating the time error, if any, and adjusting a next current measurement time point of the battery pack 10 by the calculated time error.

Although this embodiment shows a voltage measurement time point of each battery cell is later than a current measurement time point of the battery pack 10, the present invention is not limited in this regard. A voltage measurement time point of each battery cell may be earlier than a current measurement time point of the battery pack 10. In this case, it is obvious to an ordinary person skilled in the art that the step S41 is performed earlier than the step S31.

FIG. 5 is a flowchart of a method for measuring current and voltage of a secondary battery pack in synchronization manner according to another embodiment of the present invention.

According to this embodiment of the present invention, a sampling period of voltage measurement for a plurality of battery cells included in the battery pack 10 are equally fixed, and a voltage measurement time point is earlier than a current measurement time point for each battery cell.

First, the control unit 40 executes a program algorithm that enables synchronization of voltage and current measurement time points to estimate an internal resistance of the battery pack 10 (S12).

The control unit 40 provides each battery cell and its current measurement order with an index K to sequentially measure current flowing into or out of the battery pack 10 and a charging voltage of each battery cell included in the battery pack 10, and initializes the index K to 1 (S22).

The control unit 40 controls the voltage measurement circuit 30 to measure voltage (K is 1 at present) of a K^(th) battery cell, and stores a voltage measurement time point in the memory (S32).

The control unit 40 controls the current measurement circuit 30 to measure a K^(th) current (K is 1 at present) of the battery pack 10 according to a preset sampling period of current measurement, and stores a current measurement time point in the memory (S42).

The control unit 40 calculates a time difference between the voltage measurement time point and the current measurement time point stored in the memory through the steps S32 and S42 (S52).

The control unit 40 compares the calculated time difference between the voltage measurement time point and the current measurement time point calculated in the step S52 with a reference delay time stored in the memory, determines whether or not there is a time error, and calculates the time error, if any (S62).

The control unit 40 delays or advances a voltage measurement time point of a next battery cell by the time error calculated in the step S62 (S72). That is, if the time error is larger than the reference delay time, the control unit 40 delays a voltage measurement time point of a next battery cell. On the contrary, if the time error is smaller than the reference delay time, the control unit 40 advances a voltage measurement time point of a next battery cell. And, if there is no time error, the control unit 40 does not delay or advance a voltage measurement time point of a next battery cell.

The control unit 40 determines if the index K is equal to the number of battery cells included in the battery pack 10 (S82). If the index K is equal to the number of battery cells, the process goes to the step S102. If the index K is smaller than the number of battery cells, the process goes to the step S92.

In the step S92, the control unit 40 increases the index K by 1, and the process goes to the step S32.

In the step S32, the control unit 40 enables a voltage measurement of a next battery cell at a voltage measurement time point adjusted in the step S72, and stores a voltage measurement time point in the memory. Then, the control unit 40 performs subsequent steps equally as mentioned above, said subsequent steps comprising measuring a next current of the battery pack 10, storing a current measurement time point in the memory, calculating a time difference between the voltage measurement time point and the current measurement time point, comparing the time difference with a reference delay time, determining whether or not there is a time error, calculating the time error if any, and adjusting a voltage measurement time point of a next battery cell by the calculated time error.

The control unit 40 repeatedly performs the steps S32 to S92 until the index K is equal to the number of battery cells. In this way, a voltage measurement time point of each battery cell can be exactly synchronized with a current measurement time point of the battery pack 10.

Meanwhile, a step for determining whether to continue to measure a next current of the battery pack 10 and a voltage of a next battery cell and subsequent steps are the same as the above-mentioned embodiment, and their description is omitted herein.

Although this embodiment shows a voltage measurement time point of each battery cell is earlier than a current measurement time point of the battery pack 10, the present invention is not limited in this regard. A voltage measurement time point of each battery cell may be later than a current measurement time point of the battery pack 10. In this case, it is obvious to an ordinary person skilled in the art that the step S42 is performed earlier than the step S32.

The method for measuring current and voltage of a secondary battery pack in synchronization manner according to the present invention may be incorporated in the form of a program instruction that can be executed through various kinds of computer means and recorded in a computer readable storage medium. The computer readable storage medium comprises a program instruction, a data file, a data structure and so on, singularly or in combination. The program language used for the program instruction recorded in the computer readable storage medium may be designed and configured specially for the present invention or may be well known and available to an ordinary person skilled in the field of computer program. The computer readable storage medium may comprise a hardware device designed specially for storing and executing a program instruction, for example, a magnetic media such as a hard disc, a floppy disc and a magnetic tape, an optical media such as a CD-ROM (compact disc read only memory) and a DVD (digital video disc), a magneto-optical media such as floptical disc, a flash memory such as RAM (random access memory) and ROM (read only memory), and so on. The computer readable storage medium may also comprise a transmission media containing a carrier wave on which a signal designating a program instruction, a data structure and so on is conveyed, for example, an optical or metallic line, a waveguide and so on. The program instruction may comprise, for example, a machine code created by a compiler and an advanced source code executed by an interpreter. The hardware device may be configured to serve as at least one software module for carrying out the operation of the present invention, and vice versa.

Although the present invention has been described hereinabove, it should be understood that the detailed description and specific examples, while indicating preferred embodiments of the invention, are given by way of illustration only, since various changes and modifications within the spirit and scope of the invention will become apparent to those skilled in the art from this detailed description.

INDUSTRIAL APPLICABILITY

According to the present invention, a time difference between a current measuring time point of a battery pack and a voltage measuring time point of each battery cell included in the battery pack is synchronized with a reference delay time, and thus, voltage of each battery cell and current of the battery pack can be exactly measured. Accordingly, an internal resistance of each battery cell can be accurately estimated. And, even though there are changes in an operating speed of a host processor of a battery management system due to overheat, overload and so on, the synchronized state of the current measurement time point and the voltage measurement time point can be maintained. 

1. An apparatus for measuring current and voltage of a secondary battery pack in synchronization manner, comprising: a voltage measurement circuit for periodically measuring and outputting the level of a charging voltage of each of a plurality of battery cells contained in a battery pack; a current measurement circuit for periodically measuring and outputting the level of current flowing into or out of the battery pack; and a control unit for synchronizing a time difference between a current measurement time point of the battery pack and a voltage measurement time point of each battery cell with a reference delay time.
 2. The apparatus for measuring current and voltage of a secondary battery pack in synchronization manner according to claim 1, wherein the reference delay time is a time preset using trial and error.
 3. The apparatus for measuring current and voltage of a secondary battery pack in synchronization manner according to claim 1, wherein a sampling period of the voltage measurement is equally fixed.
 4. The apparatus for measuring current and voltage of a secondary battery pack in synchronization manner according to claim 3, wherein if there is a time error between a reference delay time and a time difference between a current measurement time point of the battery pack and a voltage measurement time point of a K^(th) battery cell, the control unit adjusts a next current measurement time point of the battery pack by the time error based on a voltage measurement time point of a K+1^(th) battery cell.
 5. The apparatus for measuring current and voltage of a secondary battery pack in synchronization manner according to claim 4, wherein the voltage measurement time point of the battery cell is earlier or later than the current measurement time point of the battery pack.
 6. The apparatus for measuring current and voltage of a secondary battery pack in synchronization manner according to claim 4, wherein the control unit adjusts a first current measurement time point of a next measuring cycle using a time error information obtained at the last current and voltage measurement time points of a previous measuring cycle.
 7. The apparatus for measuring current and voltage of a secondary battery pack in synchronization manner according to claim 1, wherein a sampling period of the current measurement is equally fixed.
 8. The apparatus for measuring current and voltage of a secondary battery pack in synchronization manner according to claim 7, wherein if there is a time error between a reference delay time and a time difference between a current measurement time point of the battery pack and a voltage measurement time point of a K^(th) battery cell, the control unit adjusts a voltage measurement time point of a K+1^(th) battery cell by the time error based on a next current measurement time point of the battery pack.
 9. The apparatus for measuring current and voltage of a secondary battery pack in synchronization manner according to claim 8, wherein the current measurement time point of the battery pack is earlier or later than the voltage measurement time point of the battery cell.
 10. The apparatus for measuring current and voltage of a secondary battery pack in synchronization manner according to claim 8, wherein the control unit adjusts a first voltage measurement time point of a next measuring cycle using a time error information obtained at the last current and voltage measurement time points of a previous measuring cycle.
 11. The apparatus for measuring current and voltage of a secondary battery pack in synchronization manner according to claim 1, wherein a sampling period of the voltage or current measurement is longer than a time difference between a current measurement time point and a voltage measurement time point adjacent to each other.
 12. A battery management system, comprising the apparatus for measuring current and voltage of a secondary battery pack in synchronization manner defined in claim
 1. 13. A battery pack operating apparatus, comprising the apparatus for measuring current and voltage of a secondary battery pack in synchronization manner defined in claim
 1. 14. A secondary battery pack, comprising the apparatus for measuring current and voltage of a secondary battery pack in synchronization manner defined in claim
 1. 15. A method for measuring current and voltage of a secondary battery pack in synchronization manner, comprising: (a) periodically measuring current of a battery pack and a voltage of each of a plurality of battery cells contained in the battery pack; and (b) synchronizing a time difference between a current measurement time point of the battery pack and a voltage measurement time point of each battery cell with a reference delay time.
 16. The method for measuring current and voltage of a secondary battery pack in synchronization manner according to claim 15, wherein the reference delay time is a time preset using trial and error.
 17. The method for measuring current and voltage of a secondary battery pack in synchronization manner according to claim 15, wherein, in the step (a), a sampling period of the voltage measurement is equally fixed.
 18. The method for measuring current and voltage of a secondary battery pack in synchronization manner according to claim 17, wherein, in the step (b), a reference delay time is compared with a time difference between a current measurement time point of the battery pack and a voltage measurement time point of a K^(th) battery cell, and if there is a time error between the reference delay time and the time difference, a next current measurement time point of the battery pack is adjusted by the time error based on a next voltage measurement time point of a k+1^(th) battery cell.
 19. The method for measuring current and voltage of a secondary battery pack in synchronization manner according to claim 18, wherein, in the step (a), the voltage measurement time point of the battery cell is earlier or later than the current measurement time point of the battery pack.
 20. The method for measuring current and voltage of a secondary battery pack in synchronization manner according to claim 18, wherein, in the step (b), a first current measurement time point of a next measuring cycle is adjusted using a time error information obtained at the last current and voltage measurement time points of a previous measuring cycle.
 21. The method for measuring current and voltage of a secondary battery pack in synchronization manner according to claim 15, wherein, in the step (a), a sampling period of the current measurement is equally fixed.
 22. The method for measuring current and voltage of a secondary battery pack in synchronization manner according to claim 21, wherein, in the step (b), a reference delay time is compared with a time difference between a current measurement time point of the battery pack and a voltage measurement time point of a K^(th) battery cell, and if there is a time error between the reference delay time and the time difference, a voltage measurement time point of a K+1^(th) battery cell is adjusted by the time error based on a next current measurement time point of the battery pack.
 23. The method for measuring current and voltage of a secondary battery pack in synchronization manner according to claim 22, wherein, in the step (a), the current measurement time point of the battery pack is earlier or later than the voltage measurement time point of the battery cell.
 24. The method for measuring current and voltage of a secondary battery pack in synchronization manner according to claim 22, wherein, in the step (b), a first voltage measurement time point of a next measuring cycle is adjusted using a time error information obtained at the last current and voltage measurement time points of a previous measuring cycle.
 25. The apparatus for current and voltage of a secondary battery pack in synchronization manner according to claim 15, wherein a sampling period of the voltage or current measurement is longer than a time difference between a current measurement time point and a voltage measurement time point adjacent to each other.
 26. A computer readable storage medium containing, as a program, the method defined in claim 15 for measuring current and voltage of a secondary battery pack in synchronization manner to estimate an internal resistance of the secondary battery pack.
 27. A hardware module, performing: a process for periodically measuring current of a battery pack having a plurality of battery cells connected in series and a voltage of each battery cell, comparing a reference delay time with a time difference between a current measurement time point of the battery pack and a voltage measurement time point of each battery cell, and calculating a time error between the reference delay time and the time difference; and a process for synchronizing the current measurement time point with the voltage measurement time point or vice versa by reflecting the calculated time error on a next current measurement time point of the battery pack or a voltage measurement time point of a next battery cell. 